Truck body assembly and methods of making and using same

ABSTRACT

An assembly for utility truck bodies having metal and/or composite reinforcement(s) and/or foam reinforcements and/or honeycomb reinforcement/and/or wood reinforcements encapsulated within a thermoformed thermoplastic, or thermoset or fiber-reinforced thermoset walking surface floor structure of the truck bed assembly or other composite floor structure with attachable components and junctions, e.g., sidepack(s), and methods of making the same are provided.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is related to and claims priority from the followingU.S. patent applications. This application is a continuation of U.S.application Ser. No. 16/138,394, filed Sep. 21, 2018, which is acontinuation-in-part of U.S. application Ser. No. 15/441,612, filed Feb.24, 2017, which is a continuation of U.S. application Ser. No.14/728,307, filed Jun. 2, 2015, which claims the benefit of U.S.Provisional Application No. 62/012,025, filed Jun. 13, 2014, each ofwhich is incorporated herein by reference in its entirety.

BACKGROUND OF THE INVENTION 1. Field of the Invention

The present invention relates to utility trucks, and more particularly,to an assembly for utility truck bodies and/or truck beds.

2. Description of the Prior Art

Generally, the prior art contains truck beds or bodies for use withutility trucks. Further, truck bed liners generally are known to beformed from thermoplastic materials. Truck bed modular components arealso known, including a truck bed, trailer, cargo box, and backend.Modular components may be connected to one another by known flexible orremovable connectors, such as hinges, fasteners, bolts, and nuts.Representative examples of relevant prior art US patent documentsinclude the following:

U.S. Pat. No. 6,955,385 for Corrosion-resistant body for utility vehicleby inventor Boyer filed Apr. 9, 2004 and issued Oct. 18, 2005 describesa corrosion-resistant utility body comprising a pair of body sidestorage compartment units adapted to be mounted along rear side portionsof a truck chassis and thus form a wheel well; the storage compartmentunits are formed from metal walls having side openings at the outside,an outer face plate fastened to outer surfaces of the storagecompartment assembly and door assemblies connected; weld-free utilitybody is disclosed because of the use of swage-type fasteners.

U.S. Pat. No. 8,240,732 for Trailer utility box by inventor Bernartfiled Jun. 9, 2009 and issued Aug. 14, 2012 discloses a modular storagesystem for storing items on a trailer having a plurality of containersconnected to the inside or outside railing of the trailer, at least oneof the containers positioned over a wheel of the trailer and include awheel well for housing and protecting the wheel; the utility box may besecured with fasteners, such as bolts, screws, nuts, welds, adhesivesand the like.

U.S. Pat. No. 6,786,532 for Truck body hinge assembly by inventorMcNally filed Jun. 27, 2003 and issued Sep. 7, 2004 discloses a modular,living hinge for the door of a utility truck box. The hinge assembly ismounted inside the utility body of the truck box.

U.S. Pat. No. 7,350,273 for Vehicle body hinge by inventor Skipper filedOct. 7, 2005 and issued Apr. 1, 2008 is directed to a not-living truckbody door hinge.

U.S. Pat. No. 7,784,885 for Adjustable shelving and storage system forvehicle by inventors Steiger, et al. filed Sep. 28, 2005 and issued Aug.31, 2010 discusses an adjustable storage system with one or moreadjustable storage units, which generally are polymer material shelvingpanels with supporting means integral to the panel; polymer materialshelves and drawers may be disposed between the panel supporting means.Storage units may be added by adding additional panels; a back panel maybe held in position by any suitable means but not limited to fasteners,clips, bolts, rivets, pop rivets, and the like.

U.S. Pat. No. 7,823,948 for System for shelf mounting in mobile truckbody by inventors Redman and Bauer filed Nov. 22, 2006 and issued Nov.2, 2010 discloses a system for mounting adjustable shelves in a mobiletruck body application, including integrated attachment means to receivea shelving panel for affixing thereto; the shelving panels contain atleast two slots to receive a fastener, and likewise, the integratedattachment means contain at least two slots corresponding to the slotsof the shelving panel to receive the same fastener.

U.S. Pat. No. 8,082,698 for Modular enclosure for utility trailers andpickup trucks by inventor Drake filed Feb. 26, 2010 and issued Dec. 27,2011 is directed to a light weight, modular enclosure, mounted on autility trailer or pickup truck, including foam-encapsulated panels andcorners; pieces engage via key pins and key sockets.

U.S. Pat. No. 8,117,972 for Kit and shelving system to store work toolsby inventors Winget et al. filed Jul. 9, 2008 and issued Feb. 21, 2012discusses a shelving system for storing work tools and equipment in amotor vehicle. Each of the shelves includes a reinforced composite panelof the cellular core sandwich-type.

U.S. Pat. No. 8,371,785 filed Jun. 1, 2007 and issued Feb. 12, 2013 andU.S. Pat. No. 8,696,278 filed Jan. 3, 2013 and issued Apr. 15, 2014 bothfor Rivet nut and rivet bolt and combination by inventors Babej, et al.are directed to a rivet nut with a base part and cylindrical rivetsection.

The utility truck and/or truck bed prior art is generally known toprovide thermoformed plastic components in the prior art; representativeexamples of relevant prior art US patent documents include thefollowing:

U.S. Pat. No. 7,157,034 for Twin-sheet thermoforming process byinventors Bristow, et al. filed Mar. 15, 2004 and issued Jan. 2, 2007discloses a twin-sheet thermoforming process for the manufacture ofvehicle headliners wherein the first and second sheet of superlitematerial are mounted into frames, the frames transfer the sheets into anoven where they are heated to a desired temperature using infrared (IR);the first sheet is combined with a cover-stock material usingcompression molding forming a covered first headliner part, which istransferred to a second mold station; the second sheet is heated andtransferred to the oven where it is vacuum-formed on the upper halfmold; the upper and lower mold halves are pressed together using fusingand sealing into a unified part; the superlite material is a sheet oflow-pressure, thermoformable, thermoplastic composite comprised ofpolypropylene and long chopped glass fibers.

U.S. Pat. No. 6,394,534 for Poly-bilt truck by inventor Dean filed Jan.30, 2001 and issued May 28, 2002 describes a commercial truck bodyformulated of a co-polymer material with certain strategic corners ofco-polymer material being formed by a single sheet of copolymer bentinto predetermined angle and extrusion welded on the interior portion ofthe corner; other junctions are formed using traditional fusion, buttand other joint techniques; a liquid storage tank by be integrallyformed with the body.

U.S. Pat. No. 6,389,989 for Twin sheet pressure formed pallet byinventor Hagerty filed Jan. 5, 2001 and issued May 21, 2002 describes apallet formed of a pair of thermoplastic sheets molded and fusedtogether, wherein the sheets have configurations to impart stiffness andhigh strength, and the ability of pallets to be stacked on full pallets;the molded configurations enable the sheets to be fused at a pluralityof planes including mutually perpendicular planes for high strengthunion of the sheets; the sheets are made of thermoplastic material withupper and lower sheets on shaped aluminum tools to form the palletthrough application of heat, vacuum, and/or pressure.

U.S. Pat. No. 4,606,278 for Twin sheet pallet by inventor Shuert filedSep. 28, 1984 and issued Aug. 19, 1986 discloses a twin sheet plasticsheet with no core.

U.S. Pat. No. 6,328,364 for Pull out drawer system for vehicles andtrailers by inventor Darbishire filed Feb. 17, 2000 and issued Dec. 11,2001 is directed to a pull out drawer system for trailers and vehiclesincluding a stationary mounting frame; the pull out drawer can bemounted over a wheel well. The drawers and stationary and movable framefoundations can be made of metal, such as aluminum, plastic, or wood.The preferable form includes embodiments of glass fiber reinforcedresins, plastics, such as polyolefins, or wood. The invented system issuitable for the floor of a pickup truck bed, vehicle, or trailer.

U.S. Pat. No. 6,340,194 for Hard truck bed cover by inventors Muirheadand Buckingham filed May 15, 2000 and issued Jan. 22, 2002 discusses afiber reinforced plastic cover including a top surface comprising afirst layer of layup fiberglass, a paper honeycomb reinforcing member, asecond layer of layup fiberglass, and rail inserts between the plasticlayers. U.S. Pat. No. 6,543,839 for Door or lid for a motor vehicle byinventors Gferrer and Hausberger filed Aug. 3, 1999 and issued Apr. 8,2003 discusses a door of a motor vehicle comprising an inner and outerwall of fiber-reinforced thermoplastic surrounding a core material thatis a metallic or polymer foam/honeycomb structure or light wood.

U.S. Pat. No. 6,843,525 for a load bearing floor by inventor Preislerfiled Oct. 30, 2001 and issued Jan. 18, 2005 discloses a compositevehicle load floor of the sandwich type having a cell core; the floorcomprises reinforced thermoplastic skins surrounding a core of honeycombpolyolefin.

U.S. Pat. No. 6,913,815 for Plastics-covered metal plate for car byinventors Watanabe, et al. filed Feb. 9, 2001 and issued Jul. 5, 2005 isdirected to a metal plate wherein one or both sides of the plate arecovered by a thermoplastic resin, such as polyolefin and others.

U.S. Pat. No. 7,618,075 for Hybrid truck bed liner by inventors Boddieand Morgan filed Jul. 17, 2008 and issued Nov. 17, 2009 discloses amethod to protect a vehicle wear surface with a plurality of linersections, wherein each liner section comprises a resilient layer and afabric layer, which forms a water-tight seal that comprises angledsurface edges, an overlapping joint, or combinations thereof. Thevehicle wear surface comprises a pickup truck bed or storagecompartment; the resilient layer comprises a polyolefin; and the fabriclayer comprises natural, metal, or synthetic fibers.

U.S. Pat. No. 8,397,650 for Reinforced hollow panel and method of makingb inventor Seger filed Jan. 20, 2010 and issued Mar. 19, 2013 isdirected to a hollow upper deck panel for a plastic pallet has a smoothsolid top surface and is made by thermoforming heated upper and lowertwin sheets of thermoplastics material.

U.S. Pat. No. 8,511,742 for Automobile component made of plastic byinventors Legler, et al. filed Jul. 6, 2009 and issued Aug. 20, 2013 isdirected to a vehicle component made of plastic with at least onesupporting layer and at least one outer skin. The supporting layerconsists of a thermoset, a honeycomb layer or a foam layer of plastic ormetal, and a glass fiber mat. The outer skin is preferably athermosetting plastic.

U.S. Pat. No. 8,550,544 for Vehicle body by inventor Auer filed Feb. 2,2010 and issued Oct. 8, 2013 discusses a vehicle body comprising aninner shell, an outer shell, a floor plate, and a chassis, wherein theinner shell, outer shell, and floor plate are directly or indirectlyinterconnected. When connected, this compartment is independentlyfastened to the chassis. The inner shell and outer shell is made of along fiber reinforced thermoplastic.

U.S. Pat. No. 8,690,228 for Load bearing panel assembly by inventorsMarchesano and Saur filed Jan. 31, 2013 and issued Apr. 8, 2014 isdirected to a panel assembly including at least one reinforcing assemblyof a high strength material, such as dual-phase steel; the panelassembly may be used for a vehicle floor. The appearance surface of thepanel may include a thermoplastic olefin, and the reinforcing assemblyis inserted into the mold forming the panel assembly.

U.S. Pat. Nos. 8,764,089, 8,795,807, 8,808,827, 8,808,828, 8,808,829,8,808,830, 8,808,831, 8,808,833, 8,808,834, and 8,859,074 by inventorsPreisler and Heikkila filed between Nov. 27, 2012 and Feb. 8, 2013 andissued between Jul. 1, 2014 and Oct. 14, 2014 disclose acompression-molded composite with panel first and second skins and acore positioned between the skins, wherein the skins arefiber-reinforced thermoplastics and the core is thermoplastic, cellular,or honeycomb structure; the thermoplastic is mainly polyolefin.

U.S. Pat. No. 8,844,227 by inventor Ciuperca filed Mar. 15, 2013 andissued Sep. 30, 2014 discloses a reinforcing insert consisting offiberglass or aluminum.

US Patent No. 20100119768 by inventors Simon and Robinson filed Mar. 24,2008 and issued May 13, 2010 is directed to a core product made ofthermoformable material, preferably olefinic material, and formed by atleast thermoforming. Disclosed are thermoplastic honeycomb cores andhoneycomb cores faced with fiber-reinforced resin; honeycomb cores areideal for use as a truck or trailer floor.

Aluminum or metal reinforcement is generally known in the utility truckand/or truck bed prior art; representative examples include thefollowing:

U.S. Pat. No. 7,066,532 for Ultrathin structural panel with rigid insertby inventor Shoemann filed Nov. 12, 2002 issued Jun. 27, 2006 disclosingan ultrathin covered structural panel including a panel body made fromlightweight moldable material and including one or more rigidhigh-strength inserts in the interior of the panel body, wherein theinserts are placed into the cavity of a mold that has the shape of astructural panel and a thickness of not more than about 20 mm; alightweight moldable material is introduced into the mold cavity isallowed to harden to form the structural panel, which is removed fromthe mold; the structural panel is provided for load-bearing support;steel, aluminum, and metal alloys are disclosed for the structuralinsert material.

U.S. Pat. No. 7,686,385 for Flexible truck skirt with floating mount byinventors Dolan, et al. filed Feb. 2, 2006 issued Mar. 30, 2010describes a skirt panel comprising a thermoplastic material andincluding a plurality of panel sections each having one or more ribs onits exterior; the skirt panel is mounted to the vehicle so that itprojects below the side of the vehicle, and the skirt panel can move toallow for thermal expansion and contraction without deforming it; one ormore struts are mounted between the vehicle and a lower portion of theskirt panel, and the strut is adjustable and deformable to absorb animpact to the exterior of the skirt panel; preferably the strut is madeof aluminum and is of sufficiently light gauge so that it is bendable byhand.

U.S. Pat. No. 8,221,668 discloses a pickup truck bed box two outer skinsand an expandable low density foam plastic therebetween, which embedstwo steel wire mesh grid reinforcements made of a welded meshconfiguration. Also disclosed are metal wire reinforcements or insertsembedded into polyolefin material; other insert materials are disclosed,such as load rails, pre-formed foam cores, fiberglass mesh, wood, andlow density stones.

US Patent Application Pub. No. 20040041429 for Composite panel andmethod of forming same by inventor McLaren filed May 22, 2003 publishedMar. 4, 2004 describes a panel for automotive vehicles wherein theassembly includes a first panel portion opposite a second panel portionand an intermediate material therebetween for liftgate truck bed liners.The panels are formed of a polymeric material and the intermediatematerial is a structured foam that can bond to the first and secondpanel portions; the panel portions are formed of steel, aluminum, iron,magnesium, titanium, and combinations thereof.

U.S. Pat. No. 4,330,587 for Metal-thermoplastic-metal laminates byinventor Woodbrey filed Feb. 23, 1981 and issued May 18, 1982Lightweight metal-thermoplastic-metal laminates exhibiting an improvedcombination of good formability and bending strength comprise a corelayer of a thermoplastic material selected from certain partlycrystalline polyamides and polyesters, and a metal layer of certainaluminum alloys laminated on each side of the core layer.

U.S. Pat. No. 5,197,396 for Double deck plastic pallet by, inventorsBreezer, et al. filed Aug. 5, 1991 and issued Mar. 30, 1993 is directedto a plastic pallet has a twin sheet thermoformed upper deck reinforcedwith a tubular metal substrate.

U.S. Pat. No. 6,988,757 for Composite panel and method of forming byinventors McLaren, et al. filed May 22, 2003 and issued Jan. 24, 2006discloses a bed of a pickup truck comprising inner and outer panelportions formed of a material selected from metal, such as aluminum, ora high strength thermoplastic, such as polyolefin, wherein theintermediate material is a reinforcing foam.

U.S. Pat. No. 7,194,098 for Acoustic device by inventors Azima, et al.filed Mar. 7, 2005 and issued Mar. 20, 2007 discloses a honeycomb metalor paper core and reinforced thermoplastic or metal skins.

U.S. Pat. No. 7,200,973 for Wire reinforced thermoplastic coating byinventor Tunis filed Dec. 10, 2003 and issued Apr. 10, 2007 is directedto a structural reinforcing layer made from wire, a structuralreinforcing composite layer made from wire, and the resulting loadbearing structures made from or retrofitted with wire reinforcedplastics and cements; the reinforcing layer may be molded into a loadbearing structure, such as a truck body or floor.

U.S. Pat. No. 7,575,264 for Cargo bed structure comprising fiberreinforced polymer inserts by inventor Solomon filed May 2, 2007 andissued Aug. 18, 2009 is directed to a cargo bed structure with asub-floor assembly and comprising a plurality of interlocking fiberreinforced polymer decking planks. The fiber reinforced polymerstructure may include a panel with upper and lower skins and a coretherebetween, wherein the core materials may include wood, foam, orvarious types of honeycomb.

U.S. Pat. No. 8,128,159 for Lightweight hybrid material truck beds byinventors Seksaria and Long filed Sep. 13, 2010 and issued Mar. 6, 2012is directed to a truck hood including a metal hood skin and a supportingframe including polymer and aluminum reinforcements; the polymerreinforcement comprises thermoplastic or thermoset sheets or pellets.

U.S. Pat. No. 8,413,567 for Vehicle armor by inventors Luter, et al.filed Apr. 28, 2011 and issued Apr. 9, 2013 discloses vehicle armorincluding a first layer forming an interior bottom surface of the cabinand comprised of a high-strength metal material, a second layer formingan exterior bottom surface of the cabin and comprised of a high-strengthmetal material, and, a middle layer sandwiched between the first andsecond layers and comprised of a polymer material. The middle layer iscomprised of at least one material selected from the group consisting ofa polypropylene thermoplastic composite or a glass fiber reinforcedthermoplastic composite.

U.S. Pat. No. 8,424,469 for Plastic pallet with twin-sheet deck andrunner structures by inventor Shuert filed Mar. 9, 2011 and issued Apr.23, 2013 discloses a reinforced plastic pallet comprises a twin sheetdeck structure, and a frame of reinforcing beams is encapsulated intothe interior space of the upper deck. The frame may be made of steel,aluminum or any other suitable rigid material including composites.

PCT WO1997010396 for Thermoplastic floor planks by inventors Bongartzand Neven filed Sep. 11, 1995 and issued Mar. 20, 1997 is directed to afloor plank made of a thermoplastic material, and discloses a foamedthermoplastic/thermoset material that can be reinforced with metaltubes.

Nowhere does the prior art teach or disclose the solutions provided bythe present invention. Thus, there remains a longstanding and unmet needfor providing a reinforced modular assembly for utility truck beds asdescribed in this application.

SUMMARY OF THE INVENTION

The present invention relates to an assembly for utility truck bodiesand methods of making and using them.

It is an object of this invention to provide an assembly for utilitytruck bodies, wherein the assembly includes junctions, and includesmetal and/or composite reinforcement(s) encapsulated within athermoformed thermoplastic, a fiber reinforced thermoplastic, orthermoset or fiber-reinforced thermoset floor structure of the assemblyor other composite floor structure.

It is an object of this invention to provide an assembly for utilitytruck bodies further including wall and storage compartment panelcomponents having minimal welding and/or permanent adhesive. The walland storage compartment panel components further being constructed andconfigured for modular attachment to the floor.

It is an object of this invention to provide an assembly for utilitytruck bodies that is fully integral, wherein the floor is integral withthe reinforcement system, the sidepack compartments are integral, andthe floor is integral with the sidepack, thus forming a unitaryassembly.

It is an object of this invention to reduce utility truck drag and noiseby providing utility truck sidepacks with aerodynamic features. Thesefeatures may be joined to the utility truck by removable or permanentmeans or thermoformed.

Yet another object of this invention is to provide a utility truck bodyhaving an assembly including metal and/or composite reinforcement(s)encapsulated within a thermoformed thermoplastic, a fiber reinforcedthermoplastic, or thermoset or fiber-reinforced thermoset floorstructure of the assembly or other composite floor structure andselectively including modular releasably attachable side storagecompartments connected to the utility truck bed reinforced floor.

Additionally, variations and alternative embodiments are provided in thedetailed description, and are properly considered to be included withinthe scope of the present invention.

These and other aspects of the present invention will become apparent tothose skilled in the art after a reading of the following description ofthe preferred embodiment when considered with the drawings, as theysupport the claimed invention.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view diagram of one embodiment of the presentinvention showing the full sidepack modular assembly of the utilitytruck.

FIG. 2 is a perspective diagram of a sidepack storage compartment.

FIG. 3 is a perspective diagram of a cross section of thermoplastic withmetal reinforcement.

FIG. 4 is a perspective diagram of a cross section of thermoset withmetal reinforcement.

FIG. 5 is a bottom perspective diagram of a thermoplastic floor withmetal reinforcement exposed.

FIG. 6 is a bottom perspective diagram of thermoplastic floor with metalreinforcement exposed.

FIG. 7 is a top perspective diagram of thermoplastic floor with metalreinforcement exposed.

FIG. 8 is a top perspective diagram of a floor.

FIG. 9 is a top perspective diagram of a floor.

FIG. 10 is a diagram of a continuous fiber reinforcement inthermoplastic or thermoset.

FIG. 11 is a diagram of a discontinuous fiber reinforcement inthermoplastic or thermoset.

FIG. 12 is a diagram of a particle fiber reinforcement in thermoplasticor thermoset.

FIG. 13 is a diagram of a fabric, braided fiber reinforcement inthermoplastic or thermoset.

FIG. 14 is a diagram of a foam core between thermoplastic or thermosetskins.

FIG. 15 is a diagram of a honeycomb between thermoplastic or thermosetskins.

FIG. 16 is a diagram of a wood reinforcement between thermoplastic orthermoset skins.

FIG. 17 is a diagram of a utility truck body with aerodynamic fairings.

DETAILED DESCRIPTION

Referring now to the drawings in general, the illustrations are for thepurpose of describing a preferred embodiment of the invention and arenot intended to limit the invention thereto.

Truck body in this application includes at least components for thefloor, and at least one sidepack having at least one storagecompartment. More specifically, the term “truck body” as used in thisspecification to describe the invention is defined as a structure thatmounts to the truck chassis frame rails behind a passenger cabin andincludes a floor and at least one sidepack that is constructed andconfigured to function as a sidewall to the truck bed floor; eachsidepack includes at least one storage compartment, which providesstorage space.

A truck bed is defined as the portion of the truck body that attaches tothe truck chassis frame rails and includes a surface that spans at leastthe distance between the chassis frame rails, i.e., the truck bodyincludes a truck bed assembly and at least one sidepack assembly. Thepresent invention provides an assembly for utility truck beds forproviding lightweight, reinforced flooring with removably or permanentlyattachable components that are formed of lightweight, high strengthmaterials, wherein the reinforced flooring includes metal and/orcomposite reinforcement(s) encapsulated within a thermoformedthermoplastic, a fiber reinforced thermoplastic, or thermoset orfiber-reinforced thermoset floor structure or other composite floorstructure. Material properties of the floor are selected from the groupconsisting of: electrically non-conductive, non-slip, non-reflective,flame-resistant, solvent-resistant and combinations thereof.

The present invention is related to US Pub. No. 20180126627, filed Nov.3, 2017 and published May 10, 2018, which is incorporated herein byreference in its entirety.

In a preferred embodiment, the sidepack is a fully integral unit thatalso functions as a truck body wall reinforcement, such as shown inFIGS. 1-2 . This embodiment removes the requirement for components to beassembled or connected for construction. Alternatively, the sidepack mayconsist of a shell and modular storage compartments 3 that arere-configurable within the shell. In another embodiment, the removablyattachable modular components include sidepacks that also function astruck body wall reinforcement; in preferred embodiments of the presentinvention, a plurality of modular panels are removably attached to eachother to form a sidepack. Alternatively, modular panels may bepermanently attached to each other to form a sidepack. Also,alternatively, the sidepack may be formed from components or structuresthat are larger than each of the modular panels, i.e., each of the atleast one storage compartments may be thermoformed, and removably orpermanently attached to each other to form a sidepack.

In other embodiments of the present invention, modular panels areremovably attached to each other by mechanical fasteners. Modularjunctions of the assembly of the present invention include wall,sidepack(s), and/or storage compartment panel components; mechanicalfasteners are provided for removably attaching the wall, sidepack(s),and/or storage compartment panel components with the floor section andbody of the assembly. Preferably, the sidepacks having storagecompartments are formed from modular components or panels that areconnectable or attachable using mechanical fasteners, such as bolts,rivnuts, tracks, etc., which allows for removable attachment to theoverall truck body assembly of the present invention. A sidepack storagecompartment is shown in FIG. 2 . Alternatively, modular panels may bepermanently attached by welding or chemical bonding, adhesives, etc. Inthe alternate embodiments of structures larger than single panelsdescribed in the foregoing, removable and/or permanent attachment may bevia physical bonding, chemical bonding, mechanical attachment,mechanical interlocking, magnetism, reversible adhesive, irreversibleadhesive, welding including plastic welding, and/or vacuum attachment.

In a preferred embodiment of the present invention, modular or integralcomponents, and in particular, the modular sidepack panels aremanufactured out of a thermoplastic olefin material that is formed tothe desired shape and configuration in a process of twin sheetthermoforming. The components may also be formed of a stiff compositematerial. In one embodiment, thermoplastic olefins are used forproviding a lightweight, strong assembly. The truck body flooring andsidepack(s) are formed from a thermoplastic material in one embodimentof the present invention. In a preferred embodiment of the presentinvention, a twin-sheet thermoforming process is used, having reducedcosts for manufacturing and increased strength and stiffness of thecomponents. In alternative embodiments, any type of reinforced orunreinforced thermoplastic and any type of thermoforming process, orother thermoplastic manufacturing process, such as injection molding,rotational molding, injection molding, rotational molding, compressionmolding, compression molding using unidirectional tape, compressionmolding using sheet molding compound, compression molding using bulkmolding compound, gravity fed casting, low pressure casting, highpressure casting, resin transfer molding including light resin transfermolding, 3D printing, extrusion, Digital Light Synthesis (DLS) includingContinuous Liquid Infusion Production, vacuum forming, infusionincluding vacuum infusion, hand layup, infusion, flex molding,lamination, squish molding, chop spray, and/or pultrusion are used inthe construction of the modular sidepack panels (or integral sidepacks).The thermoplastic components and the truck body assembly formed thereofprovide an assembly formed from removable or removably attachable orpermanently attached, lightweight, high strength components. Any fiberarchitecture may be used, but continuous fiber reinforcement,discontinuous fiber reinforcement, particle fiber reinforcement, andfabric braided fiber reinforcement for both thermoset 9 andthermoplastic 8 are shown in FIGS. 10-13 , respectively.

In a preferred embodiment, the sidepack structure is divided intosmaller storage compartments, like that shown in FIG. 2 , that aredesigned, constructed and configured to be waterproof or watertight toprotect equipment and/or any items that are stored inside them.Waterproof seals are provided at the interfaces, such as by way ofexample and not limitation, between the door 1 and storage compartment 3or between modular panels, and more preferably, at any joint or opening.

Regarding the doors, in a preferred embodiment, the doors 1 areremovably attached to the sidepack(s) by means of a hinge 2, which maybe constructed from metal, or other suitable material. Alternatively thedoors may be thermoformed with a “living hinge” built in. A living hingeis a thin flexible hinge that is molded into the door itself so thehinge and the door are one component made from the same material.Alternatively it may be possible to mold the doors into the front faceof the sidepack(s) with a living hinge incorporated into the design. Ifthis method were used, it would not be necessary to attach the doors tothe sidepack(s) because they would already be attached to the front faceof the sidepack(s). In yet another alternative, the doors may bepermanently attached. In another embodiment, the sidepack storagecompartments 3 may have more than one door 1, for example, one facinginto the truck bed and one facing away from the truck. This embodimentwould allow supply acquisition from inside the truck bed, which may beparticularly useful for truck beds supporting boom and lifts among othersituations.

Also, regarding the doors, in a preferred embodiment, the doors aremanufactured out of a thermoplastic olefin material that is formed tothe desired shape in a process called twin sheet thermoforming (methodsdescribed in the specification). Alternatively any type of reinforced orunreinforced thermoplastic 8 may be substituted for thermoplastic olefinin the construction of a door. Furthermore, any type of thermoforming orother thermoplastic manufacturing process such as injection molding,rotational molding, etc. may be used to form a door. Furthermore, in analternative embodiment, the doors are manufactured out of a thermoset 9or reinforced thermoset that may or may not include a foam core 7 and/orhoneycomb core 11 and/or wood core 12, which are shown in FIGS. 14, 15,and 16 , respectively. Other cores include fabric cores such as glassfabric cores. By way of example, 3D woven sandwich glass fabrics,including those woven out of e-glass fibers, carbon fibers, Kevlar®fibers, etc., such as Parabeam® 3D fabric, are used as cores in oneembodiment of the present invention. Examples of foam cores used in thepresent invention include a thermoplastic foam core, a polyurethane foamcore, a syntactic foam core, a polymethacrylimide (PMI) foam core, aPolyethylene Teraphalate (PET) foam core, a cross linked polyvinylchloride (PVC) foam core, a linear PVC foam core, and/or a polyesterfoam core. In other embodiments, a balsa core, a fiberglass core, afabric core including laminate bulkers, and/or a carbon core areutilized.

The doors may be manufactured out of thermoset through any of thesemethods: compression molding using sheet molding compound; compressionmolding using bulk molding compound; compression molding using thickmolding; compression molding using wet molding; resin transfer molding;light resin transfer molding; vacuum infusion; chop spray; and handlayup. The thermoset door may also include pultruded fiber reinforcedcomponents.

In another embodiment, reinforced or unreinforced thermoplastics arefilled or unfilled. Examples of thermoplastic fillers include inorganicfillers and mineral fillers including cast and extruded nylon orpolyamides such as Nylatron®, cast or extruded nylon or polyamides withadditives such as oil, molybdenum including molybdenum disulfide, solidlubricant including ultra-high-molecular-weight polyethylene (UHMWPE),ultra-high-molecular-weight (UHMW) fibers, bulletproof fibers such asDyneema®, polytetrafluoroethylene (PTFE) such as Teflon®, high-densitypolyethylene (HDPE), self-healing materials including self-healingelastomers, self-healing polymers, and self-healing composites such asthe self-healing materials described in “Self-healing polymers andcomposites” by T C Mauldin & M R Kessler International MaterialsReviews, 55:6, 317-346, DOI: 10.1179/095066010X12646898728408 (2010),which is incorporated herein by reference in its entirety, wax, glass,ceramics, resin, kaolin (clay), aramids such as Kevlar®, Nomex®,Technira®, etc., aluminum, alumina trihydrate, calcium sulfate, calciumcarbonate, dolomite, barium sulfate, talc, wollastonite, ultraviolet(UV) stabilizers or UV inhibitors including thermoplastic olefin (TPO),etc. TPO refers to any polymer/filler blend and more preferably topolymer/filler blends that include Polypropylene, Polyethylene, BlockCopolymer Polypropylene, rubber, and reinforcing filler. Common rubbersused in TPO's include: Ethylene Propylene Rubber, EP-diene rubber,Ethylene-Octene, Ethylbenzene, Styrene-Ethylene-Butadiene-Styrene.Common fillers used in TPO's include: Talc, Fiberglass, Carbon Fiber,Wollastonite, and Metal Oxy Sulfate.

Other fillers include organic fillers such as wood, wood flour, balsa,cellulose, shell flour, etc. Reinforced or unreinforced thermosets arealso filled or unfilled and include any of the above organic and/orinorganic fillers.

Material selection and the geometry used within a component stronglyinfluence the strength and stiffness of that component. By usingstrategic geometries such as sandwich structures and twin sheetthermoformed kiss-off locations it is possible to use reinforced orunreinforced polymers to create truck bodies that are less expensive,lighter, stronger, and stiffer than truck bodies made out of Steel andAluminum. Reinforced thermoset polymers combined with relatively thickand light weight core materials in the form of a sandwich structurecreate a very stiff yet light weight component due to the distancebetween the skin sheets, the high shear strength between the skin sheetsand the core, and the high tensile and compressive strengths of the skinsheets. Thermoplastic components manufactured in a Twin SheetThermoforming process contain two plastic sheets that are separated byan air gap with the exception of small periodic “kiss-off” locationswhere the two plastic sheets are joined via plastic-welding. The air gapbetween the majority of the two plastic sheets is at least twice thethickness of an individual plastic sheet. Alternatively, the air gapbetween the two plastic sheets is about half the thickness of anindividual plastic sheet. The gap is any distance between any two pointson the two plastic sheets in yet another embodiment. Advantageously, thegap provides for both thermal insulation and acoustic insulation for thecomponent formed by twin sheet thermoforming. The distance between thetwo plastic sheets allows the high shear strength kiss-off locations toresist most of the bending forces applied to the structure. It ispossible to fully encapsulate stiffening members between the two plasticsheets for use in applications where additional stiffness is required.Traditional materials, such as Steel, are used to produce heavy,low-cost, truck bodies. Aluminum truck bodies are lighter than steeltruck bodies, but they are the most expensive. Fiberglass reinforcedthermoset composites are currently used to produce truck bodies but themanufacturing methods and material combinations that are currently usedneed improvement. This invention teaches novel material combinations andmanufacturing methods to produce bodies made out of thermoset polymerand/or thermoplastic polymer that may or may not include reinforcement.The material combinations and strategic geometries taught in thisinvention provide highly stiff, minimally flexible characteristics anddescribe the following: Truck bed floor that deflects less than ⅛th ofan inch when 1.4 psi is applied to the entire truck bed floor when theentire truck bed weighs less than 0.030 lbs per square inch of truck bedfloor; and sidepack floor that deflects less than ⅛th of an inch when0.14 psi is applied to the entire sidepack floor when the sidepack floorweighs less than 0.015 lbs per square inch.

Regarding the truck bed as shown in FIGS. 5-9 , in one embodiment, thetruck bed assembly includes a walking surface floor 6 and externalaluminum cross members 5 underneath the walking surface floor, which ismade of a thermoplastic olefin material that is formed to the desired,predetermined shape and size in a process of twin sheet thermoforming.In an alternative embodiment having a thermoplastic flooring option, anytype of reinforced or unreinforced thermoplastic, such as continuousfiber, discontinuous fiber, particle fiber, or fabric braided fiberreinforcement (FIGS. 10-13 ), may be substituted for thermoplasticolefin in the construction of the walking surface of the floor; and anytype of thermoforming or other thermoplastic manufacturing process suchas injection molding, rotational molding, etc. may be used tomanufacture the walking surface of the floor. In an alternativeembodiment having a thermoset flooring option, walking surface of thefloor assembly may be made out of a fiber-reinforced thermoset or anunreinforced thermoset such as DCPD. It is more likely that afiber-reinforced thermoset will be used if this option is pursued.Unreinforced thermoset materials are not very common at the time of thepresent invention, but they may become more common in the future. Thethermoset floor option may be manufactured through any of these methods:injection molding, rotational molding, compression molding includingcompression molding using sheet molding compound, compression moldingusing bulk molding compound, compression molding using thick molding,and/or compression molding using wet molding, gravity fed casting, lowpressure casting, high pressure casting, resin transfer moldingincluding light resin transfer molding, 3D printing, extrusion, DigitalLight Synthesis (DLS) including Continuous Liquid Infusion Production,vacuum forming, infusion including vacuum infusion, hand layup,infusion, flex molding, lamination, squish molding, chop spray, and/orpultrusion. The thermoset floor option can also be manufactured byadhering pultruded components together. A cross section metalreinforcement within a thermoset is shown in FIG. 4 .

Also, in the floor assembly in a preferred embodiment, at least onereinforcement is provided; by way of example and not limitation,aluminum framing or tubing is encapsulated within the thermoformed floorassembly for providing a reinforced walking surface with additionalstrength. A cross section of metal reinforcement within a thermoformedfloor is shown in FIG. 3 . In an alternative embodiment, afiber-reinforced thermoset floor is provided that may or may not includeadditional reinforcement encapsulated within. In alternative embodimentsthat include additional reinforcement encapsulated within, acceptableadditional reinforcement materials are selected from foam, reinforced orunreinforced thermoplastic, metal, and combinations thereof. In thepreferred embodiment, at least one external reinforcement is provided,external aluminum cross-member 5 elements are removably attached (ornon-permanently attached) to the bottom of the walking surface floor bymeans of mechanical fasteners such as bolts, rivnuts, tracks, etc.Alternatively, the external aluminum cross-member 5 elements may beremovably attached via fasteners, or permanently attached to the bottomof the walking surface floor 6 by means of welding, chemical bonding, oradhesive. In an alternative to the preferred aluminum cross-memberelements, any type of suitable metal or fiber-reinforced thermoset maybe used. In the preferred embodiment, external aluminum cross-member 5elements extend beyond the sides of the walking surface floor of thetruck bed assembly, and function as a supporting ledge for thesidepack(s) to rest on without being affixed thereto. Note that thealuminum cross-members and the walking surface floor make up the truckbed assembly as shown in FIGS. 10-13 . In the preferred embodiment, thesidepack(s) are removably attached to the aluminum cross-member 5elements by mechanical fasteners or are alternatively permanentlyattached to the aluminum cross members by welding or chemical bonding,or adhesive. In another preferred embodiment, the floor ledges areintegrally formed with the sidepack(s).

In one embodiment, a small aerial truck body assembly is provided,including modular components having a truck bed section and at least onesidepack or side storage compartment that functions as truck wallsand/or truck wall reinforcement while also providing storage space.Also, minimal welding and/or permanent adhesive is used for the modularassembly connection, thereby providing maximum removable attachment andselective detachment of the modular components that together form theoverall truck body assembly of the present invention. The truck bedsection includes a walking surface floor component that further includesmetal and/or composite material framing to reinforce the thermoplastic 8walking surface floor, as shown in FIGS. 4-9 ; preferably, an aluminumreinforcement framing is encapsulated within the thermoplastic 8material forming the walking surface floor section. The framingfunctions to provide reinforcement for supporting the weight of at leastone human body in addition to load or cargo within the truck bodyassembly. Preferably, the assembly and in particular the floor sectionis designed, constructed and configured to hold at least between about750 lbs and about 1500 lbs per 2 ft×3 ft area. In another embodiment,the assembly is designed constructed and configured to hold at leastabout 1500 lbs per 2 ft×3 ft. Alternative to framing, metal and/orcomposite material tubing may be used to reinforce the thermoplastic 8walking surface floor. Framing is a support that does not contain a borethrough the long axis, while tubing is a support that does.

In the twin-sheet thermoforming process used in a preferred embodimentof the present invention, the method includes the following steps:providing aluminum framing/tubing reinforcement components andthermoplastic material for surrounding and enclosing the aluminumframing/tubing reinforcement; and heating and processing thethermoplastic material to form the modular assembly components,including at least a floor section with the aluminum framingreinforcement. The aluminum frames/tubes encapsulated inside thethermoplastic floor provide increased load-bearing strength.

Thermoplastic Olefin (TPO) twin sheet thermoformed materials are used inpreferred embodiments of the present invention. In preferred embodimentsof the present invention, the modular components of the assembly,including but not limited to the side packs, side storage compartments,doors, and floor section are formed from TPO. Beneficially, the TPOmaterial combined with the twin sheet thermoforming process yieldssatisfactory strength at a much lower weight than prior art materials orassemblies, including all modular components.

Also, in preferred embodiments of the present invention, the floorsection includes metal and/or composite reinforcements, such as thoseshown in FIGS. 10-13 , encapsulated inside of the TPO twin sheetthermoformed structure for providing high strength and load-bearing,while maintaining a lightweight overall component structure andassembly. In one embodiment, aluminum reinforcements, like those shownin FIGS. 3 and 4 , are used for light weight, high strength.

Thermoforming also beneficially reduces manufacturing time overtraditional truck body manufacturing methods. Manufacturing time isreduced in methods for making the modular assembly of the presentinvention due to the “all in one” thermoforming process. Nowhere in theprior art for truck body flooring sections is it taught to encapsulatealuminum framing within a plastic twin sheet floor section with athermoforming process. By contrast to the present invention, competitiveproducts and prior art known provides flooring formed of metal, such assteel or aluminum or metal alloy to provide satisfactory strength andload support.

Alternatively, other suitable materials and methods of manufacturing maybe used. By way of example, but not limitation, the assembly may includemetal and/or composite reinforcement(s) encapsulated within athermoformed thermoplastic 8, a fiber reinforced thermoplastic, orthermoset 9 or fiber-reinforced thermoset walking surface floorstructure that is part of the truck bed assembly. The selection ofmaterials and corresponding methods of making will depend upon the useof the assembly, the components, and requirements for each use.

In another embodiment of the present invention, other materials may beused as an alternative or addition to the thermoplastic materials asdescribed hereinabove. By way of definition for this application, thethermoplastic polymer chains are linear, not cross-linked. TPO andPolypropylene copolymer are examples of a material suitable for theembodiments described herein. Other materials may be selected from athermoplastic, a fiber reinforced thermoplastic, a thermoset 9 or afiber-reinforced thermoset. Similarly, for the thermoforming process thefollowing basic steps are included: at least one large plastic sheet isheated; pressure and/or vacuum are used to force the flexible plasticsheet against a tool surface for forming the shape of each component;and the final component thickness formed is typically about ½ to about⅓rd the starting gauge thickness.

Advantageously, as shown in FIG. 17 , the preferred embodiments of thepresent invention provide for aerodynamic fairings 13 that reduce formdrag and wind noise are either removably attached to the front of thesidepack(s), just behind the passenger cabin, or to the rear of thesidepack by mechanical fasteners, as set forth in the foregoing, or arepermanently attached to the front of the sidepack(s), just behind thepassenger cabin, or to the rear of the sidepack by welding or chemicalbonds. Alternatively, the fairings 13 may be molded into the front areaof the sidepack(s) or rear area of the sidepacks; no joining isnecessary with this approach because the front or back of thesidepack(s) and the aerodynamic fairing 13 is provided as a singlecomponent creating an aerodynamic sidepack.

In preferred embodiments, the aerodynamic fairings are manufactured outof a thermoplastic olefin material that is formed to the desired,predetermined shape in a process of twin sheet thermoforming. Inalternative embodiments, any suitable type of reinforced or unreinforcedthermoplastic may be substituted for thermoplastic olefin in theconstruction of aerodynamic fairings. Furthermore, any type ofthermoforming or other thermoplastic manufacturing process such asinjection molding, rotational molding, etc. may be used to form theaerodynamic fairings. Also, in preferred embodiments, a slight curve isincorporated into the sidepack(s) to further reduce form drag and windnoise while the vehicle is operating or being driven. The curve may beany form that reduces drag and wind noise. A preferred embodiment of thecurve is a taper, wherein the curve begins at the sidepack nearest thepassenger cabin and tapers toward the rear of the sidepack.

Notably, the components recited in the present invention, including butnot limited to the sidepack body including the sidepack doors, sidepackfloor, and other sidepack components integral to the sidepack orattached to the sidepack, vehicle or truck body components including thetruck bed floor, vehicle floor, vehicle or truck doors, the tailgate,truck toppers, shells, caps, tonneau covers, and any other componentwhich is attachable to any part of a vehicle, elevating platforms orsplicer platforms including platform doors, platform walls, and platformfloors are operable to be constructed out of reinforced and/orunreinforced thermoplastics and/or thermosets, including filled and/orunfilled thermoplastics and/or thermosets. Alternatively, thesecomponents are operable to be manufactured out of nylon and/orfiberglass, including pultruded fiberglass. Additionally, the componentsare operable to be manufactured via any of the techniques recitedherein, including any type of thermoforming process or otherthermoplastic manufacturing process, such as injection molding,rotational molding, compression molding, compression molding usingunidirectional tape, compression molding using sheet molding compound,compression molding using bulk molding compound, compression moldingusing thick molding, compression molding using wet molding, chop spray,gravity fed casting, low pressure casting, high pressure casting, resintransfer molding including light resin transfer molding, 3D printing,extrusion, Digital Light Synthesis (DLS) including Continuous LiquidInfusion Production, vacuum forming, infusion including vacuum infusion,hand layup, flex molding, lamination, squish molding, etc. Furthermore,the components of the present invention are operable to be manufacturedintegrally (i.e. manufactured at the same time or around the same timesuch that the components are integrally formed) or manufacturedseparately and then attached to other components or identical componentsvia physical bonding, chemical bonding, mechanical attachment,mechanical interlocking, magnetism, reversible adhesive, irreversibleadhesive, welding including plastic welding, and/or vacuum attachment.

Certain modifications and improvements will occur to those skilled inthe art upon a reading of the foregoing description. By way of exampleand not limitation, one modification may include adding golf-ball-likedimples 14 to the fairings or body to increase skin friction drag andfurther reduce form drag and wind noise. The above-mentioned examplesare provided to serve the purpose of clarifying the aspects of theinvention and it will be apparent to one skilled in the art that they donot serve to limit the scope of the invention. All modifications andimprovements have been deleted herein for the sake of conciseness andreadability but are properly within the scope of the present invention.

The invention claimed is:
 1. A sidepack door comprising: at least twosheets of thermoplastic per sidepack door including a first sheet ofthermoplastic and a second sheet of thermoplastic; wherein the firstsheet of thermoplastic and the second sheet of thermoplastic arearranged in a waterproof sandwich configuration; and wherein the firstsheet of thermoplastic and the second sheet of thermoplastic areseparated by a gap and periodically joined at kiss-off locations,thereby increasing the stiffness of the sidepack door.
 2. The sidepackdoor of claim 1, wherein the first sheet of thermoplastic and the secondsheet of thermoplastic are twin sheets of thermoformed thermoplasticformed using twin sheet thermoforming.
 3. The sidepack door of claim 1,wherein the first sheet of thermoplastic and the second sheet ofthermoplastic are fiber reinforced thermoplastic.
 4. The sidepack doorof claim 1, wherein the first sheet of thermoplastic and/or the secondsheet of thermoplastic are filled thermoplastics.
 5. The sidepack doorof claim 1, wherein the first sheet of thermoplastic and the secondsheet of thermoplastic are formed using injection molding, rotationalmolding, compression molding, compression molding using unidirectionaltape, compression molding using sheet molding compound, compressionmolding using bulk molding compound, compression molding using thickmolding, and/or compression molding using wet molding, gravity fedcasting, low pressure casting, high pressure casting, resin transfermolding including light resin transfer molding, 3D printing, extrusion,Digital Light Synthesis (DLS) including Continuous Liquid InfusionProduction, vacuum forming, infusion including vacuum infusion, handlayup, infusion, flex molding, lamination, squish molding, chop spray,and/or pultrusion.
 6. The sidepack door of claim 1, wherein the firstsheet of thermoplastic and the second sheet of thermoplastic are joinedvia physical bonding, chemical bonding, mechanical attachment,mechanical interlocking, magnetism, reversible adhesive, irreversibleadhesive, welding including plastic welding, infusion, lamination,and/or vacuum attachment.
 7. The sidepack door of claim 1, furthercomprising a foam core including a thermoplastic foam core, apolyurethane foam core, a syntactic foam core, a polymethacrylimide(PMI) foam core, a Polyethylene Teraphalate (PET) foam core, a crosslinked polyvinyl chloride (PVC) foam core, a linear PVC foam core,and/or a polyester foam core, a honeycomb core, a wood core, a balsacore, a glass fabric core including a 3D woven sandwich glass fabriccore, a fiberglass core, a fabric core including laminate bulkers,and/or a carbon core.
 8. The sidepack door of claim 1, wherein the gapis fully encapsulated by the first sheet of thermoplastic and the secondsheet of thermoplastic.
 9. The sidepack door of claim 1, wherein the gapis at least about half the thickness of the first sheet of thermoplasticor the second sheet of thermoplastic.
 10. A sidepack door comprising: atleast two thermoset panels per sidepack door, including a firstthermoset panel and a second thermoset panel; wherein the firstthermoset panel and the second thermoset panel are arranged in awaterproof sandwich configuration; wherein the first thermoset panel andthe second thermoset panel are separated by a gap and periodicallyjoined at kiss-off locations, thereby increasing the stiffness of thesidepack door; and wherein the gap constitutes space between the atleast two thermoset panels other than where the at least two thermostatpanels are joined at the kiss-off locations.
 11. The sidepack door ofclaim 10, wherein the at least two thermoset panels are manufactured viaresin transfer molding, light resin transfer molding, compressionmolding, compression molding using sheet molding compound, compressionmolding using bulk molding compound, vacuum infusion, chop spray,pultrusion, injection molding, rotational molding, or hand layup. 12.The sidepack door of claim 10, wherein the at least two thermoset panelsare fiber reinforced thermoset panels.
 13. The sidepack door of claim10, wherein the at least two thermoset panels are filled thermosetpanels.
 14. The sidepack door of claim 10, further comprising at leastone thermoplastic material.
 15. The sidepack door of claim 14, whereinthe at least one thermoplastic material includes fiber reinforcedthermoplastic material.
 16. The sidepack door of claim 14, wherein theat least one thermoplastic material includes a filled thermoplastic. 17.The sidepack door of claim 10, wherein the at least two thermoset panelsare joined via physical bonding, chemical bonding, mechanicalattachment, mechanical interlocking, magnetism, reversible adhesive,irreversible adhesive, welding including plastic welding, and/or vacuumattachment.
 18. The sidepack door of claim 10, further comprising ahoneycomb core, a wood core, a balsa core, a glass fabric core includinga 3D woven sandwich glass fabric core, a fiberglass core, a fabric coreincluding laminate bulkers, a carbon core, and/or a foam core includinga thermoplastic foam core, a polyurethane foam core, a syntactic foamcore, a polymethacrylimide (PMI) foam core, a Polyethylene Teraphalate(PET) foam core, a cross linked polyvinyl chloride (PVC) foam core, alinear PVC foam core, and/or a polyester foam core.
 19. The sidepackdoor of claim 10, wherein the gap is fully encapsulated by the firstthermoset panel and the second thermoset panel.
 20. The sidepack door ofclaim 10, wherein the gap is at least about half the thickness of thefirst thermoset panel or the second thermoset panel.
 21. A sidepack doorcomprising: at least one thermoset panel and at least one thermoplasticpanel in each sidepack door; wherein the at least one thermoset paneland the at least one thermoplastic panel are arranged in a waterproofsandwich configuration; and wherein the at least one thermoset panel andthe at least one thermoplastic panel are separated by a gap andperiodically joined at kiss-off locations, thereby increasing thestiffness of the sidepack door.
 22. The sidepack door of claim 21,wherein the at least one thermoplastic panel includes a fiber reinforcedthermoplastic panel.
 23. The sidepack door of claim 21, wherein the atleast one thermoset panel includes a fiber reinforced thermoset panel.24. The sidepack door of claim 21, wherein the at least onethermoplastic panel and/or the at least one thermoset panel is filled.25. The sidepack door of claim 21, wherein the at least onethermoplastic panel is formed using injection molding, rotationalmolding, compression molding, compression molding using unidirectionaltape, compression molding using sheet molding compound, compressionmolding using bulk molding compound, compression molding using thickmolding, and/or compression molding using wet molding, gravity fedcasting, low pressure casting, high pressure casting, resin transfermolding including light resin transfer molding, 3D printing, extrusion,Digital Light Synthesis (DLS) including Continuous Liquid InfusionProduction, vacuum forming, infusion including vacuum infusion, handlayup, infusion, flex molding, lamination, squish molding, chop spray,and/or pultrusion.
 26. The sidepack door of claim 21, wherein the atleast one thermoset panel is manufactured via resin transfer molding,light resin transfer molding, compression molding, compression moldingusing sheet molding compound, compression molding using bulk moldingcompound, vacuum infusion, chop spray, pultrusion, injection molding,rotational molding, or hand layup.
 27. The sidepack door of claim 21,wherein the at least one thermoset panel and the at least onethermoplastic panel are joined during manufacture of the at least onethermoset panel via resin transfer molding, light resin transfermolding, compression molding, compression molding using sheet moldingcompound, compression molding using bulk molding compound, vacuuminfusion, chop spray, pultrusion, or hand layup.
 28. The sidepack doorof claim 21, wherein the at least one thermoset panel and the at leastone thermoplastic panel are joined via physical bonding, chemicalbonding, mechanical attachment, mechanical interlocking, magnetism,reversible adhesive, irreversible adhesive, welding including plasticwelding, and/or vacuum attachment.
 29. The sidepack door of claim 21,further comprising a honeycomb core, a wood core, a balsa core, a glassfabric core including a 3D woven sandwich glass fabric core, afiberglass core, a fabric core including laminate bulkers, a carboncore, and/or a foam core including a thermoplastic foam core, apolyurethane foam core, a syntactic foam core, a polymethacrylimide(PMI) foam core, a Polyethylene Teraphalate (PET) foam core, a crosslinked polyvinyl chloride (PVC) foam core, a linear PVC foam core,and/or a polyester foam core.
 30. The sidepack door of claim 21, whereinthe gap is fully encapsulated by the at least one thermoset panel andthe at least one thermoplastic panel.
 31. The sidepack door of claim 21,wherein the gap is at least about half the thickness of the at least onethermoset panel or the at least one thermoplastic panel.